This invention relates to fuel cell power modules, and more particularly but not exclusively is related to fuel cell power modules located together in a common housing.
The following paragraphs are not an admission that anything discussed in them is prior art or part of the knowledge of persons skilled in the art.
Fuel cells provide a source of electrical power that can be used for a variety of different purposes. Fuel cells are commonly configured into stacks that generate useful voltages. Fuel cell stacks require a number of auxiliary components in order to function efficiently, e.g., conduits, valves, pumps, compressors and the like for delivering process gases; humidifiers for humidifying processed gases; control equipment. These additional components are commonly referred to as “balance of plant” or BOP.
To make a fuel cell stack readily useable for a variety of applications, fuel cell stacks are sometimes packaged with the associated balance of plants components to form a fuel cell power module. Such power modules can be integrated to the extent that they require no more than connections to necessary reactant supplies (e.g., hydrogen and air), and possibly a coolant (water, although sometimes air again is used as a coolant), and additionally electrical connections for the electricity generated by the fuel cell power module.
It has been proposed to use fuel cell power modules as backup power supplies. Such backup power supplies may be deployed at installations that require a high degree of integrity in their power supply and/or may be located in remote areas where a standard electricity power supply is not reliable. For example, remote transmitting towers for various functions often require backup power supplies.
In order to provide the necessary level of reliability, it is common to provide two or more power modules together. For example, sometimes three power modules are provided, with the intent that two would be sufficient to provide the necessary power and the third power module then acts as a further backup, in case one of the other two power modules fails.
The following introduction is intended to introduce the reader to this specification but not to define any invention. One or more inventions may reside in a combination or sub-combination of the apparatus elements or method steps described below or in other parts of this document. The inventor does not waive or disclaim his rights to any invention or inventions disclosed in this specification merely by not describing such other invention or inventions in the claims.
The present invention is based on the realization that where fuel cell stacks or fuel cell power modules are provided together, it may be desirable to provide common elements for the plurality of fuel cell stacks or fuel cell power modules as the case may be. In particular, it may be desirable to provide common venting arrangements to deal with any possible hydrogen leaks.
In accordance with one aspect of the present invention, there is provided an electric energy generating system, comprising:
In accordance with another aspect of the present invention, there is provided a method of ventilating a plurality of fuel cell power modules, the method comprising:
In accordance with another aspect of the present invention, there is provided a ventilation system for an electric energy generating system comprising:
In accordance with another aspect of the present invention, there is provided a fuel cell power module comprising:
For a better understanding of the present invention and to show more clearly how it may be carried into effect, reference will now be made, by way of example, to the accompanying drawings in which:
Various apparatuses or methods will be described below to provide an example of an embodiment of each claimed invention. No embodiment described below limits any claimed invention and any claimed invention may cover apparatuses or methods that are not described below. The claimed inventions are not limited to apparatuses or methods having all of the features of any one apparatus or method described below or to features common to multiple or all of the apparatuses described below. It is possible that an apparatus or method described below is not an embodiment of any claimed invention. The applicants, inventors and owners reserve all rights in any invention disclosed in an apparatus or method described below that is not claimed in this document and do not abandon, disclaim or dedicate to the public any such invention by its disclosure in this document.
Referring to
Power modules in the ventilation enclosure 10 can be intended to provide a backup power supply. For this purpose, connections need to be provided for process fluids for the power modules, for example, hydrogen gas, liquid coolant, as well as electrical power etc. In this embodiment, the power modules are based on fuel cell stacks that utilize air as the oxidant, so that no separate inlet need be provided for the air as a reactant gas, although other oxidants may be used.
An exemplary power module is shown at 40 in
At the rear of the power module 40 there is a rear flange 52 of the frame 42. On this rear flange, as seen in
In the rear flange 52, there is an extension or circular collar 56; in this embodiment, it is located centrally, but this is not essential. Extension 56 is sealed with an annular seal 86 as described below. The extension 56 and seal 86 provides for a main vent from the power module 40. Passing through the extension 56 is a hydrogen or fuel inlet 58.
On the right hand side of the rear flange 52 (again as viewed in
The frame 42 of each power module 40 includes side rails 62 that are dimensioned for a sliding fit with the rack rails 22 of the ventilation enclosure 10. In use, the power modules 40 are slid into the ventilation enclosure 10 on the rails 22, and the connection sockets 54 then make connections with conduits 70 for a coolant supply (e.g., water). The connectors 60 simultaneously make connection with electrical supply leads or bus bars.
Additionally, as shown in
The ventilation enclosure 10 including the power modules 40 will usually, but not necessarily, be placed in an indoor and non-residential environment. For such a location, there is the need to make a system safe. In particular, it will usually be necessary to ensure that any hydrogen leaks do not give rise to potentially dangerous situations, e.g., formation of explosive or flammable mixtures of hydrogen and air.
The present invention is based on the concept of a boundary of dilution. All sources of potential hydrogen leakage are placed within the boundary of dilution, and this in turn is provided with a gas tight construction. Forced ventilation is then used to ventilate the boundary of dilution to safe hydrogen concentrations during all foreseeable events.
Additionally, ventilation is interlocked with hydrogen and control valves to ensure that there is no possibility of an ignition source igniting leaked hydrogen. This means that if there is no ventilation within the boundary of dilution, then hydrogen supply to the power modules is closed off and potential ignition sources are de-energized. All components that may be exposed to hydrogen within the dilution boundary are designed to eliminate ignition sources, e.g., by the use of brushless motors. The ventilation interlock is implemented by means of a pressure switch. If there is some interruption in the supply of ventilation or the boundary of dilution, then this area may be ventilated with five volume changes, to ensure venting and discharge of any hydrogen present, before electrical components within the boundary are re-energized.
Each fuel cell power module is designed to keep residual hydrogen contained inside the boundary of dilution.
Referring to
The ventilation enclosure then includes a ventilation shaft 80, that is a generally rectangular parallelepiped; it will be understood that the exact profile and shape of the ventilation shaft does not impact its function, and it could, for example, be cylindrical or elliptical in shape. As shown in
Where a power module 40 is not present, a plug 88 can be used to close off each unoccupied connection aperture 84.
As shown in
A rear panel 94 of the ventilation shaft 80 (shown in
Turning to details of the hydrogen supply, as indicated in
The valve assembly 120 has an outlet 122 connected to a distribution pipe 106, that in turn is connected to the individual connection lines 72. As shown in
At the bottom of the ventilation shaft 80, there is provided a water level sensor 96 connected to a valve or pump 98, that in turn is connected to the bottom of the vertical shaft 80. In response to a sensed level of condensate collecting at the bottom of the ventilation shaft 80, the valve or pump 98 is actuated to discharge this from the shaft 80.
A controller 130 is provided connected to the valve assembly 120 in known manner, the controller can also be connected to a variety of acoustic or visible warning devices generally indicated at 142.
To vent the ventilation shaft 80, there is provided an exhaust conduit 150 connected to an exhaust pump or fan 152 which in turn passes through the boundary wall 102 to an exterior vent 154. A pressure switch 156 is connected to the ventilation shaft 80, with both the pressure switch 156 and pump or fan 152 being connected to and controlled by the controller 130.
Referring to
An exhaust for spent cathode gas is also provided at 118. The two exhaust outlets 116, 118 are directed through the extension 56 of the power module 40, so as to discharge into the ventilation shaft 80. A check valve 58 (
In normal use, the fuel cell stacks 46 may operate with a continuous through-flow of air as the cathode gas. For the fuel, this may be re-circulated, and may be purged on a periodic basis as required, with purging typically being carried out to prevent accumulation of contaminant gases and the like in the fuel cell stack 46.
Turning to
A pressure measuring switch 156 is shown as part of the valve assembly 120 and is connected to the controller 140.
Turning to
From the connection point 176, the line is connected through at least one further pressure reducing valve 182 and then to a solenoid valve 184 that provides connection to a further manual control valve 186, and from there the fuel is connected to the hydrogen supply line 100. A purge test valve is provided at 188.
As indicated at 190, additional and corresponding valving and other components can be provided to enable a hot swap option, i.e., to enable a new supply of hydrogen to be switched in and connected before a first supply vessel 170 is exhausted.
Referring to
In use, various leakages can occur. Any “abnormal unlimited release” can occur where a component malfunction causes a leakage. During an abnormal unlimited release event ventilation should be adequate to dilute the hydrogen mixture to below 50% LEL (Lower Explosion Limit). For “a normal mode release” this being for somewhat slow leakages and diffusion that will always be present, the ventilation should dilute the mixture to below 25% LEL.
In normal usage, a fuel cell power module may have two anode purge levels. During normal mode operation the fuel cell may purge on a regular basis, for example, by way of 40 Ipm pulse for three seconds repeated every two minutes, to give a two Ipm discharge on average.
Additionally, when a fuel stack is performing badly, the fuel cell control system can enter a “hard recovery mode” to restore the fuel cell to proper operation. In this hard recovery mode, the purge solenoid valve may be kept open until the stack has recovered. This is considered an abnormal event and covered by the “abnormal and limited release”.
With reference to
Internally within each power module 40, there is a filter 190 that is connected to a solenoid valve 192, that is in turn connected to a forward pressure regulating valve 194. The cathode blower or fan 110 is shown connected by a line 196 to the actual fuel cell stack 46. A connection 198 from the cathode gas supply line 196 to the valve 198 serves to control the pressure in the hydrogen line and depends upon the pressure of the cathode supply line. The hydrogen supply line can be biased to be either slightly above or below the pressure in the cathode line 196. A pressure sensor may be provided at 200 and is connected to a respective control unit for each power module 40.
The stack 46 is provided with a recirculation line 202 that is connected through an anode or hydrogen recirculation pump to an anode inlet of the stack 406. The exhaust lines 116, 118 for the cathode and anode, respectively, are shown for each power module and are discharged to a mixing point to within the ventilation shaft 80. A control valve 206 is provided on the anode exhaust, so that the anode exhaust may be opened and anode purging take place in a controlled manner as desired.
As shown, the vent opening 66 in the power modules 40 permit ventilation air to be drawn into the power modules and then to flow through them towards the shaft 80. The arrows then indicate that the air flows into the shaft 80 and is drawn upwards.
It will be understood that various modifications and variants are encompassed by the invention, in addition to the detailed embodiment described. For example, while each power module has been described as being largely self-contained, for reasons of economy, simplicity and even reliability, it may be preferable to provide some common balance of plant elements. For example, rather than providing a single blower in each power module, it may be preferable to provide a bank of blowers, for the cathode air supply, together and in parallel, so that if any one blower fails, the others will still be operational and capable of supplying air to all the active power modules. Other elements, e.g. a common filter for incoming air can be provided for the power modules. Aspects of the hydrant circuits in each power module and control systems may also be provided on a common basis and separate from any one power module.
Additionally, while the described embodiment envisages that each power module 40 would have its own casing that provides a completely sealed containment of the components of the power module, other variants are possible.
U.S. application Ser. No. 12/256,058 filed Oct. 22, 2008 and U.S. Provisional application Ser. No. 60/981,683 filed Oct. 22, 2007 are incorporated herein by reference in their entirety.
Number | Date | Country | |
---|---|---|---|
60981683 | Oct 2007 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 12256058 | Oct 2008 | US |
Child | 13546617 | US |